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1 .I I 26
Performance of a Large Cell-Burner Utility Boiler Retrofitted with Foster Wheeler Low-NOx Burners,
T. L. Lu, R. L. Lungren, and A. Kokkinos,
Presented at the EPNEPRI 1991 Joint Symposium on Combustion NOx Control, March 25-28, 1991, Washington, DC.
PERFORMANCE OF A URGE CELL-BURNER UTILITY BOILER RETROFITTU) W I T H FOSTER WHEELER LOW-N4( BURNERS
T. L. Lu R. L. Lungren
Arizona Publ ic Service Company Phoenix, Arizona
A. Kokkinos E l e c t r i c Power Research I n s t i t u t e
Palo A l to , C a l i f o r n i a
Presented a t the "EPA/EPRI 1991 J o i n t Symposium on
Sta t ionary Combustion NO, Control ," March 25-28. 1991, Washisgton. D.C.
ABSTRACT
A comprehensive boi ler tes t ing program was performed on Units 4 and 5 of the Four Corners Steam Electr ic Station t o compare the NOx emissions and thermal performance of a uni t r e t ro f i t t ed with low-NOx burners (Unit 4) with a " s i s t e r " unit s t i l l equipped with i t s original turbulent burners (Unit 5). Built in the l a t e 1960s. Units 4 and 5 are 800-MW Babcock & Wilcox supercr i t ical , once-through boi lers designed f o r f i r i n g of a western subbituminous.coa1. burners designed by Foster Wheeler Energy Corporation; Unit 5 was l e f t unmodified while awaiting i t s scheduled r e t r o f i t i n 1991. Major objectives of the comparative tes t ing program were t o es tab l i sh the NO, emissions levels and to assess any changes in the performance and operabi l i ty of Unit 4 due t o the ins ta l la t ion of low-NOx burners.
In 1989. Unit 4 was r e t r o f i t t e d w i t h low-NOx c i r cu la r
Testing included measurement of NOx, CO, and SO, emissions, unburned carbon, gas temperature leaving the economizer, and heat absorption in various boi le r c i r cu i t s a t d i f fe ren t levels of unit load and excess a i r , and w i t h d i f fe ren t burner a i r r eg i s t e r adjustments. burners reduced N 4 , emissions from Unit 4 by 55% compared with t h e unmodified Unit 5, without any detrimental e f fec t on boi le r performance, efficiency. o r operabili ty.
Test r e s u l t s indicate tha t the low-NO,
This paper should be of i n t e re s t t o any u t i l i t y evaluating potential NO, reductions and boi le r performance e f fec ts tha t could be anticipated'by r e t ro f i t t i ng these low-NOx burners t o pulverized-coal-fired u t i l i t y boi lers with "ce l l ", burners or conventional c i rcu lar turbulent burners.
1
INTRODUCTION
The Ar izona Pub l i c Serv ice Company (APS) operates f i v e c o a l - f i r e d u n i t s a t t h e Four Corners Steam E l e c t r i c S t a t i o n l oca ted near Farmington, New Mexico. u n i t s operate under a s t a t e environmental r e g u l a t i o n which l i m i t s emissions of n i t r o g e n ox ide (NO,) t o 0.70 lb/M8tu f rom c o a l - f i r e d u t i l i t y b o i l e r s . Th is
r e g u l a t i o n was promulgated i n 1972. severa l years a f t e r t h e two u n i t s t h a t produce t h e h ighes t NOx emissions--Uni ts 4 and 5--went i n t o commercial operat ion.
The
Babcock & Wi lcox (B&W) b o i l e r s manufactured d u r i n g t h e l a t e 1960s. l i k e U n i t s 4 and 5. were equipped w i t h c l o s e l y spaced, two- o r three-nozz le " c e l l " burners s p e c i a l l y designed t o maximize combustion i n t e n s i t y and produce extremely h igh heat re leases i n a compact burner zone. fea tures r e s u l t i n very h igh flame temperatures, heavy s lagg ing i n t h e furnace, and NO, emissions around 1.20 lb/MBtu a t f u l l load.
These combustion
Between 1972 and 1984. APS conducted severa l t e s t i n g programs and NOx c o n t r o l technology s tud ies on U n i t s 4 and 5 i n an at tempt t o achieve compliance w i th t h e s t a t e regu la t i on . None o f these e f f o r t s were successfu l o r even promising. (FWEC) Contro l 1 ed-Flow/Spl i t-F1 ame (CF/SF) low-NOx burner as a promi s i n g NO, c o n t r o l technology f o r poss ib le a p p l i c a t i o n t o t h e Four Corners b o i l e r s . Subsequent p i l o t - s c a l e burner t e s t i n g programs and des ign engineer ing s tud ies supported a r e t r o f i t o f CF/SF low-NOx burners on U n i t s 4 and 5.' I n 1987, t h e r e t r o f i t was approved f o r major overhauls o f U n i t s 4 and 5 scheduled f o r 1989 and 1991. respec t i ve l y .
I n 1985, APS i d e n t i f i e d t h e Fos ter Wheeler Energy Corporat ion
BOILER PLANT DESCRIPTION
Un i t s 4 and 5 a r e i d e n t i c a l B&W opposed-fired, s u p e r c r i t i c a l , once-through, pressur ized b o i l e r s . 5,445.000 l b / h main steam f l o w a t 1000/1000'F. s u l f u r , high-ash. subbituminous coa l w i t h t h e c h a r a c t e r i s t i c s shown i n Table 1. serv ing 18 three-nozz le c e l l burners. The c l o s e l y spaced c e l l burners
Each i s capable o f a maximum cont inuous r a t e d ou tpu t o f The u n i t s f i r e a western, low-
U n i t s 4 and 5 were o r i g i n a l l y designed by 8&W w i t h n ine p u l v e r i z e r s
3
i l lus t ra ted in Figure 1 were arranged in a nonuniform f i r i n g pattern in the furnace.
Retrofit of the FWEC CF/SF low-NOx burners (Figure 2) required major design modifications t o the Unit 4 boi le r including
a Conversion t o e ight pulverizers and 48 low-NOx burners, arranged in four rows of s i x burners on each f i r i n g wall
New lower furnace watemall panels designed f o r a conventional, widened burner spacing
Replacement of most of the burner piping a
a Ins ta l la t ion of a new pulverizer/burner control system
These construction modifications were completed during a major two-month overhaul of U n i t 4 i n the spring of 1989.
TEST PROGRAM DESCRIPTION
Following ins ta l la t ion of the low-NOx burners, APS and the Elec t r ic Power Research Ins t i t u t e (EPRI) entered in to a cooperative agreement t o t e s t and compare the modified bo i l e r ' s perfonqance and emissions w i t h the performance and emissions of unmodified Unit 5.
Specific objectives of the t e s t ing program were
a To assess any changes i n Unit 4 boi le r performance and operabi l i ty with the new low-NOx burners
To investigate the e f f ec t s of inner and outer a i r reg is te r posit ions and burner inner nozzle adjustments on flame shape and s t a b i l i t y , NO, emissions, and boi le r absorption ra tes , par t icu lar ly in the secondary superheater and pendant reheater sections
oxygen (0,) leve ls on NO, emissions
a
1 To evaluate the e f fec ts o f di f fe ren t u n i t loads and furnace excess
Tenerx Corporation was hired t o co l lec t emissions data on NO,. excess 0,. carbon monoxide (CO), and su l fu r dioxide (SO,), t o measure gas temperatures leaving the economizer, and t o co l l ec t and analyze coal and ash samples. APS
4
0
0
'II) engineers collected a l l flow, pressure, and temperature data needed t o evaluate boi ler absorption performance. inspection of the boi lers prior t o the t e s t ing program to es tab l i sh acceptable sampling locations and tes t ing procedures. Coal fineness and f u e l / a i r balance tes t ing were performed on the fuel supply systems of both uni t s pr ior t o the main tes t ing program t o ensure acceptable b o i l e r test conditions. permanent plant instrumentation used in the tes t ing was checked f o r cal ibrat ion and recal i brated where necessary.
APS and Tenerx conducted a s i t e
All
Gaseous emissions and f lue gas temperatures were measured in the f lue gas ducts between the economizer ou t l e t and the a i r preheater i n l e t s . emissions were col lected from an 18-point gr id in Unit 4 and an &point gr id .
in U n i t 5. Gas temperatures were measured from a 27-point thermocouple gr id in Unit 4 and a 24-point thermocouple gr id in Unit 5 . A computer-based data acquisit ion system was used t o co l l ec t a l l thermocouple readings.
Gaseous
TESTING PROCEDURE
The comparative tes t ing program followed the test matrix shown in Table 2 t o evaluate the un i t s ' emissions and thermal performance over a range of operating conditions. t e s t s on Units 4 and 5, along with six t e s t s conducted only on Unit 4. variables included uni t load, furnace excess 0, l eve l , burner t i p position. and inner/outer a i r r eg i s t e r position. The following tests were conducted:
The tes t plan consisted of a s e r i e s of 15 paral le l Test
fl Four full- load paral le l t e s t s were run on both uni t s a t standard burner t i p position of +3 inches a t low (1.8-2.4%). normal (2.7- 2.9%). and high (3.4-3.6%) excess 0, levels .
Four full-load, paral le l tests were run on both uni t s with burner t i p pos i t i ons moved t o zero and -3 inches a t low (1.8-2.4%) and h i g h (3.4-3.6%) excess 0, levels.
Four full- load tests were run on Unit 4 only while varying inner and outer a i r r eg i s t e r positions. excess 0, l eve ls (2.7-3.0%). posit ions were ident i f ied based on NOx emission leve ls . additional full- load tests were then r u n on U n i t 4 with both a i r r eg i s t e r s a t optimized posit ions a t low (2.0%) and normal (2.7%) excess 0, levels .
I
1
These tests were performed a t normal Optimum inner and outer a i r r eg i s t e r
Two
a 5
Four 75% load, paral le l t e s t s were r u n on b o t h uni ts under standard burner operating conditions with a l l mil ls i n service (AMIS) and with top mill out of service (MOOS) a t normal excess 0, levels (3.2-3.7%); and with AMIS a t high excess 0, levels (4.4-4.5%).
Three 50% load, paral le l t e s t s were r u n on both uni t s under standard burner operating conditions with two top MOOS a t normal excess 0, l eve ls (4.7-5.0%), and then with two top MOOS 0, (5.4-5.5%).
0
Each t e s t las ted about 4-5 hours--1.5 hours of process s tab i l iza t ion , and 3-4 hours of actual tes t ing . point samples and as composite samples. of a chemiluminescent NOx analyzer, infrared analyzers f o r CO and C02. a zirconia ce l l analyzer f o r 0,. and a DuPont SO, analyzer.
Emissions were monitored and recorded as single- Emissions tes t ing equipment consisted
Two fuel analyses were performed during each t e s t . Coal samples were collected immediately downstream of the coal silos before the coal entered each mill feeder. coal sample. and higher heating value (HHV). proximate, and ultimate analyses were performed. Mineral analyses were also conducted on selected coal samples.
These samples were r i f f l e d together t o produce an "average"
Bottom ash samples were collected once per test from a selected bottom ash hopper. one economizer hopper f o r each unit . Samples were analyzed f o r mineral consti tuents, fusion temperature, and carbon carryover ( loss on ignit ion. LOI). bottom ash and baghouse f l y ash samples.
Fly ash samples were collected from two selected baghouse hoppers and
Size, quantity, and elemental analyses were performed on selected
A t the end of Test No. 1 a severe leak in the f i r s t point high-pressure feedwater heater of U n i t 5 occurred, and the heater had t o be valved out of service. Testing revealed tha t NOx emissions from U n i t 4 were approximately the same with t h i s f i r s t p o i n t heater in or out of service. Based on t h i s , the Unit 4 f i r s t point heater was also valved out of service for the remaining paral le l t e s t s t o allow a f a i r performance comparison between Units 4 and 5. During the s i x t e s t s on only Unit 4 , both f i r s t point heaters were in service.
6
EMISSION TEST RESULTS
Because the secondary a i r supply t o the burners o u t of service on Unit 5 could n o t be shut of f , a staging e f f ec t was present t h a t could explain the lower NO, emissions from U n i t 5 under low-load conditions. emissions versus stoichiometric a i r r a t i o t o cor rec t for the staging effect .
Figure 3 i l l u s t r a t e s NO,
The FWEC low-NO, burners ins ta l led on Unit 4 achieved an average 50% reduction in NO, emissions versus those from the unmodified Unit 5 when operating a t fu l l load. reduction in NO, emissions was 47% with AMIS, and 40% with the t o p MOOS. the two top MOOS a t 50% load conditions. the staging e f f ec t on U n i t 5 NO, emission reduction was so obvious tha t only an average 17% NO, reduction was observed on Unit 4.
Under 75% load and normal (3.4-3.7%) excess 0, levels. the With
Figure 4 i l l u s t r a t e s NO, emissions versus uni t load a t various operating excess 0, levels. between NO, emissions and unit load f o r Unit 5. while the Unit 4 data did not show signif icant correlat ion. which i s a small portion of to ta l NO, emissions. burners on U n i t 5 were operated a t higher peak flame temperatures than the low-NO, burners on Unit 4, Unit 5 produced more thermal NO, than Unit 4. and was more sensi t ive t o uni t load changes.
A correlation analysis indicated a def in i te correlat ion
0 Reducing u n i t load can only reduce thermal NO,. Because the turbulent
Figure 5 indicates tha t changing the burner t i p posit ion had l i t t l e e f f ec t on NO, emissions. When the burner t i p position i s adjusted, the primary a i r velocity i s changed because primary airflow i s constant. t o optimize the primary airlsecondary a i r r a t i o t o minimize shear-induced turbulence. previously ident i f ied the optimum burner t i p posit ion as +3 inches.
Adjustments are used
APS had They may also cause major changes i n flame shape.
The e f fec ts of inner and outer a i r reg is te r posit ion on the performance of the low-NO, burners in U n i t 4 a re i l l u s t r a t ed in Figure 6. regulate the amount of swirl in the secondary a i r near the burner t i p and control the point of flame ignition. Outer a i r reg is te rs impart i n i t i a l swirl
Inner a i r reg is te rs
e 7
to the secondary air and control the overall flame shape and size/strength of the internal recirculation zone. Minimum NO, emissions levels occurred at an inner air register position of 10' open and an outer air register position of 35-40' open. positions, NO, emission levels were 0.44 lb/MBtu at normal excess 0, level and 0.42 lb/MBtu at low excess 0, level.
With both inner and outer air registers in their optimum
Figure 7 illustrates the NO, emissions versus burner zone liberation rate. The effect of staging on Unit 5 NO, emissions is obvious.
SO, flue gas values ranged from 605 to 914 ppm for Unit 4, and 546 ppm to 761 ppm for Unit 5. CO emissions ranged from 32 to 75 ppm except on one test with low excess 0,, where average CO emissions were 185 ppm.
CO emissions on Unit 5 ranged from 32 to 75 ppm, while Unit 4
Analyses of coal and ash samples taken during the testing program revealed the consistency of the coal fired in Units 4 and 5. The coal is fairly reactive, so there was little difference in the unburned carbon levels between Units 4 and 5.
BOILER PERFORMANCE TEST RESULTS
Based on preliminary analyses of boiler performance data, it appears that there was no detrimental effect on boiler performance, efficiency, or operability as a result of the installation of low-NOx burners on Unit 4. Table 3 presents the results of a typical, full-load, boiler performance test. Further analysis is required to explain the substantial differences between some of the comparative data. emissions testing on Unit 5 after the installation of low-NO, burners. will provide additional data for a better comparison of the boiler performance before and after the burner retrofit.
APS plans to conduct boiler performance and This
Furnace €xi t Gas Temperature (FEGTL
The FEGTs at full-load operations calculated using the back-calculation method ranged from 2541 to 2680'F for Unit 4, and 2647 to 2850'F for Unit 5. The
8
.
d i f f e rence i n FEGT f o r U n i t 4. which ranges f rom 100 t o 209'F lower than U n i t 5 FEGT, i s due t o increased furnace heat abso rp t i on as a r e s u l t o f reduced l e v e l s o f s lagging i n t h e furnace. temperature flame reg ions which promote s lagging.
Heat Absorpt ion Rates i n B o i l e r C i r c u i t s
Changes i n t h e burner f i r i n g arrangement and t h e r e t r o f i t o f low-NOx burners have c rea ted a new furnace heat absorp t ion pa t te rn . t y p i c a l comparison o f heat absorp t ion ra tes i n t h e b o i l e r c i r c u i t s f o r U n i t s 4 and 5.
The low-NOx burners c o n t r o l h igh-
F igu re 8 i l l u s t r a t e s a
Only en tha lp ies f o r the b o i l e r c i r c u i t s are shown i n t h e f i g u r e because t h e water/steam r a t e s f o r U n i t s 4 and 5 are almost i d e n t i c a l . an increase o f 31-66% i n the upper furnace hea t absorp t ion r a t e compared w i t h U n i t 5. Th is i s due t o reduced l e v e l s o f s lagg ing i n t h e furnace. A decrease o f 33-43% i n t h e pr imary superheater heat absorp t ion r a t e i s a l s o i n d i c a t e d i n the U n i t 4 data. The heat absorp t ion ra tes f o r t h e upper furnace and pr imary superheater a r e be ing i n v e s t i g a t e d f u r t h e r t o f i n d o u t why t h e r e are subs tan t i a l d i f f e rences between t h e u n i t s . absorpt ion r a t e increases t h e pr imary superheater o u t l e t steam temperature such t h a t t h e superheater spray f l o w requirement f o r U n i t 4 i s increased by 148-180% when compared w i t h U n i t 5. U n i t s 4 and 5 data show i n s i g n i f i c a n t changes i n t h e heat absorp t ion r a t e s i n o the r b o i l e r c i r c u i t s such as t h e lower furnace, secondary superheater, superheater enclosure, reheater, and economizer
U n i t 4 data shows
The much h ighe r upper furnace heat
Main Steam and Hot Reheat Temperatures
Data i n d i c a t e a s l i g h t increase i n t h e main steam temperature f o r U n i t 4. Main steam temperatures a r e i n t h e range o f 990-1004'F f o r Unit 4 versus 983- 992°F f o r U n i t 5. However, t he re i s a subs tan t i a l decrease i n t h e h o t reheat temperature f o r Uni t 4. 977'F f o r U n i t 4 and 975-1011'F f o r U n i t 5. reheater i n l e t gas temperature f o r U n i t 4, which i s 124-177'F lower than t h e temperature f o r U n i t 5.
on t u r b i n e c y c l e e f f i c i e n c y i s be ing i nves t i ga ted .
Hot reheat temperatures a r e i n t h e range o f 947- Th is i s due t o t h e pendant
The e f f e c t o f lower h o t reheat temperature f o r U n i t 4
9
B o i l e r E f f i c i e n c i e s
B o i l e r e f f i c i e n c y increased s l i g h t l y , i n t h e range o f 0.72-1.52%. f o r Unit .4.
This i s due t o lower a i r preheater i n l e t gas temperatures as a r e s u l t o f lower economizer i n l e t water temperatures. Dur ing t h e o n l y t e s t t h a t U n i t s 4 and 5 had w i t h bo th f i r s t p o i n t h igh-pressure feedwater heaters i n se rv i ce (Test No. 1). the a i r preheater o u t l e t gas temperatures were almost the same. Therefore. i t can be concluded t h a t t h e b o i l e r thermal e f f i c i e n c i e s remained the same a f t e r t h e r e t r o f i t .
r
CONCLUSION
The b o i l e r emissions and thermal performance t e s t i n g program comparing t h e performance o f U n i t s 4 and 5 a t t h e Four Corners Steam E l e c t r i c S t a t i o n revealed t h a t t h e r e t r o f i t o f low-NOx burners t o U n i t 4 reduced NOx emissions by about 50% a t normal, f u l l - l o a d opera t ing c o n d i t i o n s w i thou t any de t r imenta l e f f e c t on b o i l e r performance, e f f i c i e n c y . or o p e r a b i l i t y .
The average l e v e l o f NO, emissions f rom Unit 4 was 0.53 lb/MBtu. w e l l under the app l i cab le s t a t e o f New Mexico a i r - q u a l i t y standard o f 0.70 lb/MBtu.
ACKNOWLEDGMENTS ~
Special thanks t o Four Corners operat ions, maintenance, and engineer ing personnel f o r t h e i r ass is tance i n conduct ing t h e t e s t i n g , t o Char les A l l e n f o r h i s techn ica l assistance, and t o Paul Thompson o f Tenerx f o r conduct ing the t e s t i n g .
I
10
FIRING WSITWN
I PRIMARY AIR
F igure 1 - FWEC Three-Nozzle C e l l Burner
Figure 2 - FWEC Controlled-Flow/Split-Flame Low-NO, Burner
11
1
I
Figure 3 EFFECT OF STOICHIOMETRY ON
NOx EMISSIONS NOx. LBlMBTU 1.3
1.2
1.1
1
0.9
0.8
0.7
0.6
0.5
0.4 0.9 1 1.1 1 2 1.3 1.4 1.5
STOICHIOMEIRIC AIR wno
Figure 4
EFFECT OF BOILER LOAD ON NOx EMISSIONS
NOx. LBlMBTU
i j i j 1
1.4
i 12 j : :..= i + , ............. ............. ............. ........ ........................... ........... +? ........ i i
- F ........................... ..... ................... . ............ .........
............ ............. .............. ............. .............
. ........ ............. ............. ............. ............
i i
' 0 j
: o ;
X UNIT W G H 0 2
0 UNITSH1GH02
X UNIT4 IOW02
UNITS-LOWOZ ............. ............. ............. ............. ............. ......... .........
1 i i + i ' ; i -
.
0.8 i _.___._______,_____________~ UNm5
A 0.6 .&
0.4
02
j j 0
400 450 500 550 600 650 700 750 800
LOAD, MW I N 4
12
1 . I ,
............... ............... ............... ................ ................ ................ ............... ................ ...... ............... ................ ................ ................ ............... ................
............... ............... ............... ................ ................ ............... ......
0.8 I I 1 i i : L
i i I i L i
0 6 I L i i : 4 0 5 .............. -9'.... ................
i 0 - 0.4 ............... i ............... i ............... i ................ ; ................ 1 ................ i ............... i ............... 0.3 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Figure 6 EFFECT OF AIR REGISTER POSITION ON
NOx EMISSIONS FULL LOAD NO% LBlMBTU
: 1 3 ................ i ................ i ................ i ................ i ................ i ................ i ................ i ................. 1.2 .... 1.1 .... ....... ................ ................ ................ ................. - OUTER AIR REGISTER .......
.... X INNER REG w/LOWER 02 ....... ................ ................ ................ ............ : .... 0.8 ....
i i 0.3 . . . . ; . . . . ; . . . . ; . . . . , . . . . , . . . . ; . . . . ; . . . .
0 10 20 30 40 50 60 70 80
AIR REGISTER POSITION, % OPEN
13
1.4 - 1.2
1
I ........ ........(................ ; ................ ; ........ *..."+ ................
................. I ................ :.+ ............ :
..... . . o UNIT4
+ UNIT5
I( UNITTTAGING
i + : +;
i j ................ ; i : ............... j o
! o j
.........
: * 0 * - ............... 6 ____.____._____~ ............... ................
i ................ ............... . . .....
Figure 8
0.6 - 0 4 -
0.2 i
0 .
COMPARISON OF SECTIONAL
............... ............... ....~a ........... : ..... ............... ............... 0 ; ; & p j ; i 1 0
;0 j $ i ............... i ............... ; ............... i i ................ ; 4 ......a i
j
i : I i I i ;
, .
................ ............... ...... ................ :
............... ............... ................ ............... ............... ................ ................ ............... : . . . . . . . . ; , ; , . " ~ ' " ' ~ " ~ ' " ' ' ' " " ' ~ " " ~
HEAT I ENTHALPY IBTUILB)
r
4BSORPTION ----- : .............. ..............
1500 A
.............. ............... ........ .............. .............. .... +- UNIT5
.............. .................. ..i ...............
I < .............._... ............ I &!wLc _.... .......... * .............. 2 ............... !
............... : ............... ........................... I i
R. 1 F i
................... ............... .............. .............. j L L I .............. I ............... : i i i
FN.1P : : .............. ............... ... . ,
14
. - ' .
Test Proximate Ana lys is
% Mo is tu re % Ash
% V o l a t i l e s
% F ixed Carbon
Energy Content. B tu / l b
% S u l f u r
MAF, B t u / l b % A i r Dry Loss
U l t imate Ana lys is
% Mo is tu re % Carbon
% Hydrogen
% N i t rogen
% S u l f u r
% Ash
% Oxygen
Table 1
COAL ANALYSES SUMMARY
Cond i t ion
-- As Received Dry Basis As Received Dry Basis As Received Dry Basis As Received Dry Basis As Received Dry Basis --
--
-- As Received Dry Basis As Received Dry Basis As Received Dry Basis As Received Dry Basis As Received Dry Basis As Received Dry Basis
U n i t 4
14.67 16.33 19.14 26.47 31.02 42.53 49.84
9561 11205
0.85
U n i t 5
14.34 16.32 19.05 31.32 36.88 37.75 44.07
9602 11210
0.72 1.00 0.84
9.03 7.57 13857 @
14.67 53.87 63.13
3.86 4.52 1.10 1.29 0.85 1 .oo
16.33 19.14 9.32
10.92
14.34 54.55 63.68
3.96 4.62 1.15 1.34 0.72 0.84
16.32 19.05 8.96
10.47
15
Table 2
TEST MATRIX
Test Number 1 2 3 4
5
6
7
a 9 10 11 12 13 14 15 16 17. 18 19 20 21
-Un i t s 100% 4&5
100% 4&5
100% 4&5
100% 4&5
100% 4
100% 4
100% 4
100% 4
100% 4&5
100% 4&5
100% 4&5
100% 4&5
75% 4&5
75% 4&5
75% 4&5
75% 4&5
50% 4&5
50% 4&5
50% 4&5
50% 4&5
50% 4&5
Excess Air Normal Normal Low
Normal Normal Normal Normal Normal Low
H i g h Low
High Normal High Normal Normal Normal High Normal Normal Normal
16
Test Condition Std. Nozzle & Register Positions Std. Nozzle & Register Positions Std. Nozzle & Register Positions Repeat Std. Outer Register Open Outer Register C1 osed Inner Register Open Inner Register Closed Burner Nozzle In (0) Burner Nozzle In (0)
Burner Nozzle In (-3) Burner Nozzle In ( -3) Std., All Mills In Service Std., All Mills I n Service Std., 1 Mill Out o f Service Std. Std.. 2 Mills O u t o f Service Std., 2 Mills O u t o f Service Repeat Std. Optimal Nozzle Register Positions Optimal Nozzle Register Positions
Table 3
I TYPICAL COMPARATIVE BOILER PERFORMANCE OATAI
Ut.IL7-5 i Parameter ?DSL%+V&+ Pres Rct-coitt I
Load, MW
Excess 0,. % Wet Feedwater Flow, 1000 l b / h Superheater Spray Flow, 1000 Main Steam Temp., 'F Hot Reheat Temp., 'F Furnace E x i t Gas Temp.,'F NO,, lb/MBtu
760 2.82
5478 1 b/h 433
1004 965 2593
0.49
752 2.74
5493 286 992 999 2775
17
1991 Joint Symposium on Stationary Combustion NO, Control-EPAIEPRI n ~-
Volume 1: Sessions 1,2,3,4A, and 48
Sponsored by ELECTRIC POWER RESEARCH INSTITUTE
Generation and Storage Division Palo Alto, California
and
US. ENVIRONMENTAL PROTECTION AGENCY Air and Energy Engineering Research Laboratory
Research Triangle Park, North Carolina
March 25-28, 1991 The Capitol Hilton Washington, D.C.